ソースコード

diff #

class Combination:
    def __init__(self, n_max, MOD=10 ** 9 + 7):
        """
        PREP = O(n_max + log(MOD))
        :param self.fac[n]: n!
        :param self.facinv[n]: 1/n!
        """
        self.mod = MOD
        f = 1
        self.fac = fac = [f]
        for i in range(1, n_max+1):
            f = f * i % MOD
            fac.append(f)
        f = pow(f, MOD - 2, MOD)
        self.facinv = facinv = [f]
        for i in range(n_max, 0, -1):
            f = f * i % MOD
            facinv.append(f)
        facinv.reverse()

    def __call__(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] * self.facinv[r] % self.mod * self.facinv[n-r] % self.mod

    def F(self, n):
        """ n! """
        return self.fac[n]

    def C(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] * self.facinv[r] % self.mod * self.facinv[n-r] % self.mod

    def P(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] * self.facinv[n-r] % self.mod

    def H(self, n, r):
        """ (箱区別:〇 ボール区別:× 空箱:〇) 重複組み合わせ nHm """
        if n==r==0: return 1
        if not 0 <= r <= n+r-1: return 0
        return self.fac[n+r-1] * self.facinv[r] % self.mod * self.facinv[n-1] % self.mod

    def rising_factorial(self, n, r):
        """ 上昇階乗冪 n * (n+1) * ... * (n+r-1) """
        return self.fac[n+r-1] * self.facinv[n-1] % self.mod

    def stirling_first(self, n, k):
        """ 第 1 種スターリング数  lru_cache を使うと O(nk)  # k 要素を n 個の巡回列に分割する場合の数 """
        if n == k: return 1
        if k == 0: return 0
        return (self.stirling_first(n-1, k-1) + (n-1)*self.stirling_first(n-1, k)) % self.mod

    def stirling_second(self, n, k):
        """ 第 2 種スターリング数 O(k + log(n)) """
        if n == k: return 1                              # n==k==0 のときのため
        return self.facinv[k] * sum((-1)**(k-m) * self.C(k, m) * pow(m, n, self.mod) for m in range(1, k+1)) % self.mod

    def grouping(self, n, k):
        """ (箱区別:× ボール区別:〇 空箱:×) 組み分け   mSn。第二種スターリング数と添え字を交換したもの """
        if n == k: return 1                             # n==k==0 のときのため
        return self.facinv[n] * sum((-1)**(n-m) * self.C(n, m) * pow(m, k, self.mod) for m in range(1, n+1)) % self.mod

    def sum_groupiing(self, n, k):
        """ (箱区別:× ボール区別:〇 空箱:〇) 重複順列    Σ_(l=1,...,n) mSl """
        return sum(self.grouping(n,m)for m in range(1, k+1)) % self.mod

    def balls_and_boxes(self, n, k):
        """ (箱区別:〇 ボール区別:〇 空箱:×) 組み分け    mSn * n!  O(k + log(n)) """
        return sum((-1)**(n-m) * self.C(n, m) * pow(m, k, self.mod) for m in range(1, n+1)) % self.mod

    def bernoulli(self, n):
        """ ベルヌーイ数。べき乗和を求める際に必要(Faulhaber の定理。 lru_cache を使うと O(n**2 * log(mod)) """
        if n == 0: return 1
        if n % 2 and n >= 3: return 0  # 高速化
        return (- pow(n+1, self.mod-2, self.mod) * sum(self.C(n+1, k) * self.bernoulli(k) % self.mod for k in range(n))) % self.mod

    def faulhaber(self, k, n):
        """
        べき乗和 0^k + 1^k + ... + (n-1)^k
        bernoulli に lru_cache を使うと O(k**2 * log(mod))  bernoulli が計算済みなら O(k * log(mod))
        """
        return pow(k+1, self.mod-2, self.mod) * sum(self.C(k+1, j) * self.bernoulli(j) % self.mod * pow(n, k-j+1, self.mod) % self.mod for j in range(k+1)) % self.mod

    def lah(self, n, k):
        """ n 要素を k 個の空でない順序付き集合に分割する場合の数  O(1) """
        return self.C(n-1, k-1) * self.fac[n] % self.mod * self.facinv[k] % self.mod

    def bell(self, n, k):
        """ n 要素を k グループ以下に分割する場合の数  O(k**2 + k*log(mod)) """
        return sum(self.stirling_second(n, j) for j in range(1, k+1)) % self.mod

    def montmort(self, n):
        """ 順列を置換した数列のうち、ai != i となるような数列の数 """
        return sum( (-1)**(k%2) * self.fac[n]*self.facinv[k] for k in range(2,n+1)) % self.mod

class Combination2:
    """ without mod """
    def __init__(self, n_max):
        f = 1
        self.fac = fac = [f]
        for i in range(1, n_max+1):
            f = f * i
            fac.append(f)

    def __call__(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] // self.fac[r] // self.fac[n-r]

    def F(self, n):
        """ n! """
        return self.fac[n]

    def C(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] // self.fac[r] // self.fac[n-r]

    def P(self, n, r):
        if not 0 <= r <= n: return 0
        return self.fac[n] // self.fac[n-r]

    def H(self, n, r):
        """ (箱区別:〇 ボール区別:× 空箱:〇) 重複組み合わせ nHm """
        if n==r==0: return 1
        if not 0 <= r <= n+r-1: return 0
        return self.fac[n+r-1] // self.fac[r] // self.fac[n-1]

def is_prime_MR(n):
    if n in [2, 7, 61]:
        return True
    if n < 2 or n % 2 == 0:
        return False
    d = n - 1
    d = d // (d & -d)
    L = [2, 7, 61] if n < 1<<32 else [2, 3, 5, 7, 11, 13, 17] if n < 1<<48 else [2, 3, 5, 7, 11, 13, 17, 19, 23] if n < 1<<61 else [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37]
    for a in L:
        t = d
        y = pow(a, t, n)
        if y == 1: continue
        while y != n - 1:
            y = (y * y) % n
            if y == 1 or t == n - 1: return False
            t <<= 1
    return True

def prime_counter(n):
    i = 2
    ret = {}
    mrFlg = 0
    while i*i <= n:
        k = 0
        while n % i == 0:
            n //= i
            k += 1
        if k: ret[i] = k
        i += 1 + i%2
        if i == 101 and n >= 2**20:
            while n > 1:
                if is_prime_MR(n):
                    ret[n], n = 1, 1
                else:
                    mrFlg = 1
                    j = _find_factor_rho(n)
                    k = 0
                    while n % j == 0:
                        n //= j
                        k += 1
                    ret[j] = k

    if n > 1: ret[n] = 1
    if mrFlg > 0: ret = {x: ret[x] for x in sorted(ret)}
    return ret

def divisors(n):
    """ O(x^1/4)  O(10**9)の整数10**4個の約数列挙が可能 """
    primes=prime_counter(n)
    P=set([1])
    for key, value in primes.items():
        Q=[]
        for p in P:
            for k in range(value+1):
                Q.append(p*pow(key,k))
        P|=set(Q)
    P = sorted(list(P)) # 速度が欲しい時は消す
    return P

def _find_factor_rho(n):
    m = 1 << n.bit_length() // 8 + 1
    for c in range(1, 99):
        f = lambda x: (x * x + c) % n
        y, r, q, g = 2, 1, 1, 1
        while g == 1:
            x = y
            for i in range(r):
                y = f(y)
            k = 0
            while k < r and g == 1:
                ys = y
                for i in range(min(m, r-k)):
                    y = f(y)
                    q = q * abs(x - y) % n
                g = gcd(q, n)
                k += m
            r <<= 1
        if g == n:
            g = 1
            while g == 1:
                ys = f(ys)
                g = gcd(abs(x-ys), n)
        if g < n:
            if is_prime_MR(g): return g
            elif is_prime_MR(n//g): return n//g


##############################################################################################
import sys
from math import gcd
input = sys.stdin.readline

MOD = 10**9+7
N,K=map(int, input().split())

C = Combination(100000, MOD=MOD)

res=1
for p,cnt in prime_counter(N).items():
    res*=C.H(K+1,cnt)
    res%=MOD
print(res)